Valerio Lorenzoni scite author profile

Rod-Airfoil PIV Sound Acoustic Analogy Curle's Analogy Aeroacoustic analysis of a rod-airfoil flow by means of timeresolved PIV Left: Predicted wave fronts that are emanating from the airfoil Right: Predicted directivity pattern, green dots represent measurements Problem area The present paper investigates the feasibility of prediction of vortexstructure noise based on time resolved Particle Image Velocimetry (PIV). We consider the case of an airfoil immersed in the wake of a cylindrical rod.

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Two techniques for PIV-based aeroacoustic prediction and their application to a rod-airfoil experiment

Moore

Lorenzoni

Scarano

2010

Exp Fluids

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In this paper, we discuss techniques by which the aeroacoustic properties of the turbulent flow in a rod-airfoil benchmark experiment can be inferred from time-resolved PIV measurement. While acoustic measurements can be made directly using microphones, the proposed techniques provide a means to directly link acoustic waves with specific flow events, which is invaluable in devising noise mitigation strategies. The approaches are possible thanks to recent improvements in digital and camera technology that can provide time-resolved measurements in air flows, necessary for the determination of unsteady flow quantities related to aeroacoustic production. Both techniques are based on Curle's acoustic analogy, where one is based on Lagrangian determination of the required quantities, while the other requires all flow quantities to be converted into Fourier modes. Application of both techniques yields results that are in reasonable agreement with microphone noise measurements for the rod-airfoil experiment.

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Music-based biofeedback to reduce tibial shock in over-ground running: a proof-of-concept study

Berghe

Lorenzoni

Derie

et al. 2021

Sci Rep

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Methods to reduce impact in distance runners have been proposed based on real-time auditory feedback of tibial acceleration. These methods were developed using treadmill running. In this study, we extend these methods to a more natural environment with a proof-of-concept. We selected ten runners with high tibial shock. They used a music-based biofeedback system with headphones in a running session on an athletic track. The feedback consisted of music superimposed with noise coupled to tibial shock. The music was automatically synchronized to the running cadence. The level of noise could be reduced by reducing the momentary level of tibial shock, thereby providing a more pleasant listening experience. The running speed was controlled between the condition without biofeedback and the condition of biofeedback. The results show that tibial shock decreased by 27% or 2.96 g without guided instructions on gait modification in the biofeedback condition. The reduction in tibial shock did not result in a clear increase in the running cadence. The results indicate that a wearable biofeedback system aids in shock reduction during over-ground running. This paves the way to evaluate and retrain runners in over-ground running programs that target running with less impact through instantaneous auditory feedback on tibial shock.

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The SoundBike: musical sonification strategies to enhance cyclists’ spontaneous synchronization to external music

Maes

Lorenzoni

Six

2018

J Multimodal User Interfaces

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